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세종대학교
곽관웅

페이스북 트위터 카카오톡 네이버밴드 링크복사

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공학 >기계ㆍ금속 >기계공학
강의학기

2022년 2학기

조회수

19,093

강의계획서

This course introduces the basic priciples of feedback control of dynamic system, related system analysis technics, and the design of the controller satisfying the given dynamic specifications. To achieve the course goals, system odeling technics descrbing the dynamic systems into mathematical differential equations, technics (root locus, Nyquist) analyzing the dynamic characteristics (stability, tranqusient response) in both time and frequency domain ill be studied. Also, PID and lead-lag controller design method that makes the system dynamic characteristics satisfy the required specifications will be investigated.

수강안내 및 수강신청
※ 수강확인증 발급을 위해서는 수강신청이 필요합니다

Introduction to Feedback Control

차시별 강의

1.		Introduction to Feedback Control
		The Laplace Transform
2.		The Laplace Transform (Inverse Laplace Transform, Partial Fraction Expansion)
		Solving linear time-invariant differential equations using L.T.
3.		Transfer Functions, Impulse response
		Block diagrams, block diagram reduction
4.		Block diagram reduction, Signal flow graph (1)
		Block diagram reduction, Signal flow graph (2)
		Signal flow graph, Mason’s rule (1)
		Signal flow graph, Mason’s rule (2)
5.		State space representation
		Converting s.s. to a T.F. and TF to SS
6.		Linearization-1st order system, 2nd order system (1)
		Linearization-1st order system, 2nd order system (2)
		Linearization-1st order system, 2nd order system (3)
7.		2nd order system, Higher order systems, Stability analysis
		Higher order systems, Stability analysis, Steady-state errors in unity feedback control systems
8.		Static error constant, Steady-state error for nonunity feedback
		Root-Locus Analysis (Root-Locus plots, pole-zero cancellation)
9.		Root-Locus Analysis (Nonminimum phase system, positive feedback system, conditionally stable system) (1)
		Root-Locus Analysis (Nonminimum phase system, positive feedback system, conditionally stable system) (2)
		Control Systems Design by the Root-Locus Method (Lead compensation)
10.		Control Systems Design by the Root-Locus Method (Lag compensation, Lead-Lag compensation)
		Control Systems Design by the Root-Locus Method (Lead-Lag compensation, paralle compensation, velocity feedback)
11.		Frequency Response Analysis (Bode plots of first-order factors)
		Frequency Response Analysis (Bode plots of first-order & quadratic factors)
12.		Frequency Response Analysis (system types and log-magnitude curve)
		Frequency Response Analysis (polar plots)
13.		Frequency Response Analysis (Nyquist stability criterion)
		Frequency Response Analysis (Nyquist stability criterion, relative stability)
14.		Control Systems Design by Frequency Response (Lead compensation, Lag compensation, Lead-Lag compensation)